A system and method for incorporating occupancy-detecting technology into furniture is provided. More particularly, the invention relates to detecting occupancy by a standalone capacitance detection device. The standalone capacitance detection device is configured for integration with any number of furniture items. Further, the detected capacitance may be used to determine commands for controlling a variety of devices associated with the standalone capacitance detection device. Additionally, methods for determining occupancy of a furniture item and a system for monitoring occupancy are described herein.
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1. A standalone capacitance detection system for integration with a furniture item, the system comprising:
one or more light sources;
a capacitance detection sensor; and
a control component configured for communicative coupling to the one or more light sources and the capacitance detection sensor, wherein the control component:
receives a first capacitance indication from the capacitance detection sensor;
generates a first lighting command based on the first capacitance indication, wherein the first lighting command initiates a light-on state for the one or more light sources;
controls a power supplied to the one or more light sources based on the first lighting command, wherein the power is supplied in a plurality of on intervals during the light-on state;
coordinates with the capacitance detection sensor to detect a second capacitance indication during the light-on state, wherein the capacitance detection sensor detects capacitance between the plurality of on intervals of the supplied power;
generates a second lighting command based on the second capacitance indication, wherein the second lighting command initiates a light-off state; and
controls the stopping of the power supplied to the one or more light sources based on the second lighting command.
12. A method of manufacturing a standalone capacitance detection system, the method comprising:
communicatively coupling one or more light sources to a control component;
communicatively coupling a capacitance detection sensor to the control component;
wherein the control component communicatively coupled to the one or more light sources and the standalone capacitance detection device is configured to:
receive a first capacitance indication from the capacitance detection sensor;
generate a first lighting command based on the first capacitance indication, wherein the first lighting command initiates a light-on state for the one or more light sources;
control a power supplied to the one or more light sources based on the first lighting command, wherein the power is supplied in a plurality of on intervals during the light-on state;
coordinate with the capacitance detection sensor to detect a second capacitance indication during the light-on state, wherein the capacitance detection sensor detects capacitance between the plurality of on intervals of the supplied power;
generate a second lighting command based on the second capacitance indication, wherein the second lighting command initiates a light-off state; and
control the stopping of the power supplied to the one or more light sources based on the second lighting command.
7. A method of controlling a standalone capacitance detection system associated with a furniture item, the method comprising:
controlling power to one or more light sources communicatively coupled to a control component;
receiving one or more capacitance indications from a capacitance detection sensor communicatively coupled to the control component;
receiving, at a control component, a first capacitance indication from the capacitance detection sensor;
generating, by a control component, a first lighting command based on the first capacitance indication, wherein the first lighting command initiates a light-on state;
controlling, by a control component, the power supplied to the one or more light sources, wherein the power is supplied in a plurality of on intervals during the light-on state;
coordinating, by a control component, with the capacitance detection sensor to detect a second capacitance indication during the light-on state, wherein the capacitance detection sensor detects capacitance between the plurality of on intervals of supplied power;
generating, by a control component, a second lighting command based on the second capacitance indication, wherein the second lighting command initiates a light-off state; and
controlling, by a control component, the stopping of the power supplied to the one or more light sources based on the second lighting command.
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This application is a continuation-in-part of U.S. Nonprovisional patent application Ser. No. 14/810,355, filed Jul. 27, 2015, entitled “Characterization and Calibration for Automated Furniture,” which is a continuation-in-part of U.S. Nonprovisional patent application Ser. No. 13/854,720, filed Apr. 1, 2013, entitled “Occupancy Detection for Furniture,” now U.S. Pat. No. 9,089,223 (issued Jul. 28, 2015), which is a continuation-in-part of U.S. Nonprovisional patent application Ser. No. 13/749,120, filed Jan. 24, 2013, entitled “Capacitive Wire Sensing for Furniture,” which is a continuation-in-part of U.S. Nonprovisional patent application Ser. No. 13/346,386, filed Jan. 9, 2012, entitled “Capacitive Wire Sensing for Furniture,” the entire contents of each of which are hereby incorporated by reference.
Not applicable.
The present invention generally relates to occupancy-detecting technology incorporated into furniture. More particularly, the invention relates to a standalone capacitance detection device, a method for detecting occupancy, and a system for monitoring occupancy.
Some prior occupancy detection and automatic lighting solutions have used passive infrared sensors to detect motion. However, any motion within the room or near the furniture can activate such sensors, thereby falsely indicating occupancy. For example, a dropped pillow, or an arm dangling off the bed, can trigger a false indication of presence and/or cause a light to turn on in response to detection. Further, pets moving about the space may also cause similar problems. Additionally, a lack of motion within the room can cause prior systems to indicate a lack of occupancy in a room, when in fact, the room is occupied.
The present invention generally relates to a system and method for occupancy detection in a variety of furniture environments. It should be understood that the invention contemplates incorporating a standalone capacitance detection device and/or system into a variety of furniture items, both bedding and otherwise, and that the invention is not limited to the specific item for which occupancy detection is provided.
In one embodiment, a standalone capacitance detection device is provided. The standalone capacitance detection device may include a capacitance detection sensor for detecting and/or sensing capacitance measurements and a control component for generating and communicating various commands. In some aspects, the standalone capacitance detection device may additionally include one or more light sources and/or a manual control device. The control component may, for example, operate to generate commands based on the detected capacitance, which may cause the one or more light sources to change lighting states.
Another exemplary embodiments of the invention relates to a method for determining occupancy of a furniture item based on capacitive detection. The method may include receiving, by a standalone capacitance detection device, a first indication of an occupancy state, wherein the first indication of an occupancy state corresponds to a first change in capacitance detected by the standalone capacitance detection device. The method may also include receiving, by the standalone capacitance detection device, a second indication of an occupancy state, wherein the second indication of an occupancy state corresponds to a second change in capacitance detected by the standalone capacitance detection device. Further, the method may include communicating, by the standalone capacitance detection device, the second indication of an occupancy state. The communicated occupancy state may be used, for example, to change a lighting state of one or more light sources associated with the standalone capacitance detection device.
In another illustrative aspect, an occupancy monitoring system for monitoring use and/or occupancy of furniture items based on capacitance detection is provided. The system may include, for example, a standalone capacitance detection device coupled to a furniture item and an occupancy monitoring service. The system may generally operate to detect frequency and/or duration of use of a furniture item in any number of settings. For example, the system may be implemented by a hotel, a hospital, or an individual consumer to monitor how and when various furniture items are used.
Additional objects, advantages, and novel features of the invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following, or may be learned by practice of the invention.
The present invention is described in detail below with reference to the attached drawing figures, wherein:
An embodiment of an automated bedding system 10 with capacitive wire sensing is seen in
When viewed from the top in
As shown in
Capacitive wire segments 20 and 22 may be used to detect presence or absence of a person or other being on top of the automated bedding system 10. For example, as arranged near first end 14 of the automated bedding system 10, the torso of a person positioned on the top of the automated bedding system 10 may be detected by capacitive wire segments 20 and 22. In embodiments, capacitive wire segments 20 and 22 create a defined sensing area on the top half of the head of the bedding system 10, and are less susceptible to noise interference from articulation of the rest of the automated bedding system 10.
Referring next to
In some embodiments, third segment 24 is made from a single capacitive wire, while in other embodiments, multiple capacitive wire segments are coupled to the control enclosure 18. As will be understood, additional capacitive components, such as capacitive wire segments, may be coupled to the control enclosure 18, and arranged on the bottom of the plurality of panels 12. For example, additional capacitive wires arranged perpendicular to each other may be coupled to the control enclosure 18. In further embodiments, third segment 24 is made from a capacitive material other than wire.
Capacitive wire segment 24 may be used to detect presence or absence of a person or other being below the automated bedding system 10. For example, as arranged around the perimeter of the bed at both the first and second ends 14 and 16, a person or other body underneath the automated bedding system 10 may be detected by capacitive wire segment 24. In embodiments, based on detecting presence underneath the bedding system 10, bed articulation may be stopped. As viewed from the side in
Referring next to
In some embodiments, in alternative or in addition to positioning of capacitive wiring around the perimeter of the panels 12 that support an adjustable mattress, conductive wire is attached around the perimeter of the mattress itself. As shown in the adjustable bed 32 of
The capacitive wire may be routed through some or all of the tape edge around the perimeter of a mattress 28. Additionally, a tape edge may be applied to both the top and bottom edges of the mattress 28, and both the top and bottom tape edges 34 and 36 may include a capacitive wire. Accordingly, the sensitivity of the capacitive wire in the top tape edge 34 may be adjusted independently from the tape edge 36 surrounding the perimeter of the bottom of the mattress. For example, a small change in voltage detected by the capacitive wires in the top tape edge 34 of the mattress may indicate that a user has moved on the surface of the mattress, but is still on the bed. By contrast, a small change in voltage detected by the capacitive wires in the bottom tape edge 36 of the mattress may indicate that a person, or other being, is below the bed. In either case, different features associated with the automated bedding system 10 may be activated based on whether presence is detected above the bed (via capacitive wires in the top tape edge 34) or below the bed (via capacitive wires in the bottom tape edge 36).
In further embodiments, a capacitive component may be incorporated into the mattress covering 38 of a mattress 28, as shown in
In some embodiments, a capacitive component may be incorporated into a platform-style bed. For example, a lower portion of a bed that does not articulate, such as a box spring or a mattress frame 30, may include a capacitive component that detects presence from above. In one embodiment, a capacitive wire is attached in a loop around the perimeter of the top of the frame 30, in
Presence may also be detected using a loop of capacitive wire incorporated inside a mattress. For example, as shown in
A defined sensing area is created by routing of a capacitive wire around a perimeter of a furniture item, in a variety of configurations such as those described above. For example, a capacitive wire routed around the perimeter of a mattress, such as in the tape edge around a perimeter of the top surface of a mattress, creates a defined sensing area on the area of the mattress surrounded by the sensing perimeter. As such, a person's presence within the sensing area may be detected by the capacitive wire, which a processor may use to determine when a person exits or enters a bed. A processor coupled to the capacitive component may be housed in a control enclosure, such as control enclosure 18. In one embodiment, the control enclosure 18 is mounted below the platform of an automated bedding system 10. In further embodiments, the control enclosure 18 is mounted generally beneath the mattress 28.
In embodiments, capacitive wire incorporated into the perimeter of a mattress is used to monitor a change in capacitance over a specified amount of time. The capacitive component (capacitive wire) is adapted to have a voltage based on proximity of an object to the capacitive component. Such voltage information is collected via the capacitive component and received by the processor, which determines when a change in voltage satisfies a threshold. Once a particular change in capacitance satisfies a threshold, a corresponding function associated with the automated bed may be initiated. In embodiments, a threshold for initiating a corresponding function includes a particular amount of change in voltage within a particular amount of time. For example, when using capacitance information to turn lights on/off, a particular amount of change in voltage may be required during a particular amount of time before satisfying the threshold indicating that a person has exited the bed (and before the lights may be turned on). Similarly, a particular threshold value of voltage change may be required by the processor, over a particular amount of time, before making a determination that a person has re-entered the bed (and before the lights can be turned off again). In embodiments, a processor continuously receives capacitance monitoring information, and monitors how quickly a change in capacitance occurs (how quickly the delta changes) to determine if a big enough change has occurred in a certain amount of time to satisfy a threshold, and trigger the corresponding function.
Based on satisfying a particular threshold, various features associated with the automated bedding system 10 may be activated and/or enabled. For example, an alarm clock may only be triggered if a person's presence is detected in the bed (i.e. if a threshold amount of change in voltage is detected during capacitance monitoring over a particular amount of time). In another example, additional bedding features may be activated based on presence detection by capacitive wires. Such additional integrated bedding features include having a massage motor activated to wake up a user. If a user is not present in the bed, and therefore not detected using the capacitive wires, the lack of presence detection will prevent the massage motor from running at a particular scheduled time.
A variety of other functions of the automated bedding system 10 may be controlled based on detection with a capacitive wire. In other words, a processor coupled to the capacitive wire may initiate a variety of functions based on received data indicating presence or lack of presence, as determined using capacitance information. Different functions may be controlled, such as stopping a bed from articulating when presence is detected beneath the bed, turning on/off lights based on a person exiting/entering a bed, and controlling other accessories or electrical/household appliances through internal circuitry associated with the processor. In one example, after presence is no longer detected in the bed (thereby indicating that a person has exited the bed) lights may be turned on. Additionally, when the person returns to the bed, the lights may turn off.
A variety of communication protocols may be used to control the variety of functions described above. For example, a two-way controller using ZigBee® wireless communication protocol may be used. In some embodiments, a two-way communication protocol intended for use in automation (similar to Bluetooth®) may be utilized. One embodiment of the invention may be controlled by an external sensor only, with all of the components necessary for the sensor that plug into an existing motor. In another embodiment, two separate microcontrollers may be used: one dedicated primarily for sensing purposes that, when it detects something, sends a signal to a secondary device/microcontroller that is programmed to initiate the corresponding response.
Turning now to
With reference next to
Referring now to
In the example of
In
In embodiments, a thin-gauge perimeter wire may be installed around a perimeter of an adjustable bed and/or frame of an adjustable bed. In embodiments, the thin-gauge perimeter wire may be coupled to the base of an adjustable bed using tape; adhesives; fasteners; staples; or may be embedded or extruded through foam; covered in a thin foil tape; or attached via one or more additional/alternative hardware mechanisms. In one embodiment, the perimeter wire may be embedded in foil tape prior to application to the bedding device, as in the example of
In embodiments, the foil tape and the perimeter wire are capacitively coupled and sensitive to touch. That is, similar to the capacitive wire segments used to detect presence or absence of a person or other being on top of an automated bedding system, foil tape and a perimeter wire coupled to a frame or base of an adjustable bed may also be capacitively coupled and able to detect presence or absence based on a detected change in capacitance. Further, such capacitance detection may be adjusted to a required amount of sensitivity for presence detection, such as “fine tuning” the microcontroller and/or software for detection using thicker upholstery.
In a further embodiment of the invention, ports, grommets, and/or sockets are added to an automated bedding mattress construction to allow connection of a capacitive wire to spring an assembly, thereby creating a capacitive array internal to the mattress. As discussed with reference to
In some embodiments, body capacitance can be used to operate different types of switches as a capacitive touch sensor will respond to close-proximity detection of a change in capacitance. Accordingly, the tip of a finger may be detected by a capacitive sensor, with a minimal amount of pressure (i.e., triggered without forceful touching), and the capacitive sensing system of an automated furniture item may detect minimal amounts of bodily contact.
Turning next to
In one embodiment, when a person contacts the adjustable bed frame 114, the frame's normal capacitance is increased. In response to the increase in capacitance by contact with the bed frame 114, the controller 120 measures the change in capacitance of the bed frame 114 against a known capacitance of the frame. In embodiments, controller 120 may be mounted to the bed frame 114 directly, with a separate microcontroller for a sensor, and a separate microcontroller for controlling the bed motion. Accordingly, a sensing microcontroller may use separate channels for wire detection of presence (discussed above) and frame detection of presence. In embodiments, the use of a coax 118 to directly connect the bed frame 114 to the controller 120 reduces the amount of interference caused during monitoring and/or detection, as the coax exits the controller 120 and will not detect any signals until it reaches the bed frame 114.
In one example, as connected to the bed frame 114 via coax 118, controller 120 measures capacitance by pulsing the bed frame 114 with a voltage, such as a low voltage having a minimal amount of current. In between pulses from the controller 120, the signal fed into the controller's analog to digital converter (ADC) is used to measure how much the voltage changes over time. In one embodiment, one microcontroller of the controller 120 may send out a charge, with the resulting charge being read by another microcontroller having a processor that monitors how quickly the detected charge decays. In one embodiment, when a body is in contact with the frame, the controller 120 monitors how quickly the change in capacitance rises, and how far the change in capacitance rises.
Based on detection of a change in capacitance by the controller 120, the actuator of the adjustable bed frame 114 may be disabled during a motion operation if it is determined that human contact is detected. In embodiments, the controller 120 may monitor the overall levels of capacitance of the bed frame 114 to determine what changes in capacitance do and do not satisfy a threshold for determining that contact has been made. For example, the rate of change and the amount of change may be monitored to determine whether a threshold for contact has been met, and whether the travel of the bed frame 114 should be altered. In embodiments, when triggered by a controller 120, the actuators of an adjustable bed 112 may be programmed to stop all motion (such as downward motion) when contact is detected by the conductive, metal bed frame 114. In such an example, when presence of a human is detected underneath a moving, adjustable bed 112, the detection by bed frame 114 may indicate to the controller 120 to discontinue travel of the bed frame 114. In another embodiment, in response to detection of a human underneath a moving, adjustable bed 114, the actuators may reverse and/or retract motion by a particular distance, such as backing up an inch if the bed frame 114 was lowering to a downward position when presence was detected.
Accordingly, to re-start travel once a condition has been met for stopping travel by the controller 120, a user may indicate to the adjustable bed 112 that 1) the condition that triggered the indication of presence has gone away, and/or 2) that the user has again selected motion of the adjustable bed frame 114 by providing an indication to the controller 120 (such as pushing a button on a controller of the adjustable bed 112). In further embodiments, controller 120 may track the usage of an adjustable bed 112, and the subsequent commands received after detecting presence near a moving bed frame 114. Such tracking may be used to designate specific actions required by the bed in response to presence detection, such as moving of a bed into a fully-upright position, or discontinuing motion of the bed prior to initiating a subsequent lowering once presence is no longer detected.
With reference to
As will be understood, “traditional” bushings used in adjustable beds or motion furniture are often made with electrically-insulating acetals, which prevent the transfer of a charge during detection of capacitance. Accordingly, in some embodiments, parasitic capacitive coupling may be used to capacitively couple components of the adjustable bed or motion furniture metallic assemblies. In a further embodiment, jumper wires are used to connect components of an adjustable bed that are electrically isolated due to non-conductive bushings. For example, electrically-isolated parts of a metal, adjustable bed frame may be coupled to other conductive portions of the bed frame using jumper wires.
In embodiments, bushings and other washer materials being carbon-fiber filled acetal with moderate surface conductivity may be used. Such bushings and washers may assist in the transfer of energy throughout a metal, adjustable bed frame 114, its components, and related assemblies. In some embodiments, a metallic bed frame may be capacitively coupled to other assemblies in the adjustable base. Accordingly, the term “metallic assembly” may be used to refer to any of the frame, components of the frame, and assemblies of an adjustable furniture item, such as a bed.
In one embodiment, acetal carbon-fiber filled bushings are less than or equal to the surface resistivity of 1.0E+3 ohm and have a volume resistivity of 1.0E+3 ohm centimeter (using test methods per IEC 60093). The human body capacitance is the input to the metallic assembly, and the carbon-fiber filled bushings act as “jumper wires” to transmit energy between the metallic assemblies in adjustable beds and motion furniture. In one embodiment, electroceramics (ceramic materials specifically formulated for electrical properties) may be tailored for use as a highly-conductive bushing material, such as the electronically conductive ceramic consisting of Indium Tin Oxide (ITO), Lamthanum-doped strontium titanate (SLT), and yttrium-doped strontium titanate (SYT).
Turning next to
As can be seen in
With reference to
With reference to
Turning next to
With reference to
As will be understood, a variety of filtering techniques may be used to adjust the determinations made (regarding whether presence is or is not detected) using software associated with the processor. For example, a variety of filters or transforms may be applied to the monitored capacitance signal to adjust/adapt the software for a particular application or user. For example, an automated bedding system could be adapted to adjust lighting or other functions based on particular amounts of change in capacitance over particular amounts of time, or trigger particular functions during particular times of day/night. As such, a processor may be trained to alter the sensitivity of a threshold based on previous use by a particular user of a corresponding feature. Additionally, a reaction time may be changed and a threshold may be adjusted for different users and different features of the automated bed.
An embodiment of an automated bedding system 210 with capacitive wire sensing is seen in
When viewed from the top in
In some embodiments, detection pads 218 and 220 are a capacitive material, adapted to have a voltage based on proximity of an object to the detection pads 218 and 220. In further embodiments, the detection pads 218 and 220 are an aluminized polymer material with conductive properties. The aluminized polymer material of detection pads 218 and 220 may be conductive on one side only. In one embodiment, detection pads 218 and 220 are Mylar® pads. The capacitance measured across such conductive, aluminized polymer pads may be monitored by a processor that uses software to generate a determination of occupancy detection. In further embodiments, detection pads 218 and 220 may be aluminized Mylar®, aluminum sheets, metal screening, aluminum tape, a wire grid for a seat board, a metalized material or fabric, or any aluminized polymer material with conductive properties. In some embodiments, detection of occupancy the system activates one or more features and/or accessories via a control box and signal acting as a switch, using technologies such as Bluetooth, Wi-Fi, and Zigbee. In some embodiments, detection pads 218 and 220 have a single side that is conductive, and may be coupled to a bottom surface of an automated bedding system 210 platform, such as being sandwiched between stationary parts of an automated bedding system 210 during assembly.
In one embodiment, a Microchip® brand capacitive sensor may be used to determine when occupancy is detected. As such, while occupancy detection relies on the juxtaposition of a person or body with respect to one or both of the detection pads 218 and 220, a determination of the level of detection or the measurement of occupancy is conducted digitally, in software associated with the processor. In some embodiments, software associated with the occupancy detection system includes a software protocol that provides for seamless control of remote accessories associated with an automated bedding system.
As shown in
Detection pads 218 and 220 may be used to detect occupancy with respect to an automated bedding system 210. For example, as arranged near first end 214 of the automated bedding system 210, the torso of a person positioned on the top of the automated bedding system 210 may be detected by detection pads 218 and 220. In embodiments, detection pads 218 and 220 create a defined sensing area on the top half of the head of the bedding system 210, and are less susceptible to noise interference from articulation of the rest of the automated bedding system 210.
Referring next to
In some embodiments, wire grid 226 provides similar occupancy detection functionalities as the detection pads 218 and 220. Additionally, although depicted in
Turning now to
In some embodiments, a detection material associated with the automated bedding system 210 may be coupled to a top side of a plurality of panels 212 and/or a bottom side of the plurality of panels 212, and may be coupled directly to the deck of the automated bedding system 210 (i.e. to at least a portion of the plurality of panels 212). The detection materials depicted in
With reference now to
As shown in the automated bedding system 246 of
For example, detection pads 252 in
In one embodiment of the invention, an aluminized, polymer detection material may be tied directly to a helical spring of an automated bedding system for detection. For example, a detection material may be coupled to an innerspring unit of an automated bedding system, to create a single sensor from the combined detection of each spring in the innerspring unit. In another embodiment, individual pocket coils of a mattress could become individual occupancy detectors as the coils are insulated from one another. As such, the pocket coils could serve as an array of individual sensors. In some embodiments of the invention, capacitive detectors such as aluminized polymer pads may be used with an automated bedding system mattress that includes pocket coils, memory foam, and/or air. For example, two or more aluminized polymer material sensors may be coupled to a platform of an automated bedding system to generate at least two distinct zones of detection with respect to be bed. In some embodiments, aluminized polymer material sensors and/or pocket coils could be used to identify multiple, individual areas and/or zones on a bed for detection of occupancy.
Various embodiments of the invention utilize the occupancy detection systems of
The features triggered by changes in occupancy detection may be dependent on the time of day during of the occupancy determination. For example, upon determining a change in occupancy at a particular time of night (i.e. a determination that a user has exited a bed in the middle of the night) may trigger the turning on of lights associated with a bathroom, such as a light in the bathroom and/or a series of lights along a path to the bathroom. In further embodiments, a change in occupancy detection may trigger one or more features associated with a remote controller of an automated bed. For example, an occupancy change may trigger an alarm to chime, which could turn on one or more lights in response to triggering the remote. In further embodiments, features that are activated/triggered by a change in occupancy detection (such as a detection panel sensing the absence of a person) could be deactivated and/or timed out after a particular amount of time. In another embodiment, a snooze feature may be incorporated into the detection system such that an occupancy detection that triggers a particular feature of the automated bedding system may be postponed and/or delayed.
In one embodiment of the invention, the occupancy detection system may be provided for use with a non-adjustable bed, such as a child's bed. As such, a detection pad, detection grid, and/or detection strip feature discussed in
In embodiments of the invention, occupancy detection triggers both activation and deactivation of features associated with a bed. For example, an occupancy detection system may determine that a person has entered a bed, which may trigger the system to turn off the lights in the room. Accordingly, in one embodiment, a first change in occupancy determination (a user exiting a bed) may trigger lights to be turned on in a room, while a second change in occupancy determination (a user returning to bed) may trigger the lights to turn back off. In some embodiments, lights may be dimmed upon sensing a user getting into bed, timed to turn off after a particular amount of time passes after occupancy is detected, and/or dimmed to dark upon occupancy detection. For example, lights may be dimmed to dark upon detection of an occupant returning to bed.
Further embodiments of the invention include coordinating of additional features associated with the occupancy detection system, such as a home alarm system that may be set and/or turned on based on detecting that a person has gotten into bed. In further embodiments, the home alarm system may be deactivated upon the person exiting the bed. In yet another example, exterior lights of a house may be turned on based on detecting a user exiting the bed, such as a front porch light turning on when a user exits the bed in the middle of the night.
In one embodiment, the occupancy detection system may be used in a home care situation for an elderly or disabled individual. Accordingly, the system may be programmed to trigger certain alarms when the elderly or disabled person gets out of bed, such as by chiming a remote and/or alarm feature of the occupancy detection system. In another embodiment, various features of a user's home may be coordinated to operate in response to determinations by the occupancy detection system. For example, if the occupancy detection system determines that a user is in bed, the home environment system (i.e. the Heating, Ventilation and Air Conditioning (HVAC) system) may be adjusted to a user-specified night setting. Similarly, if the occupancy detection system determines that a user has exited a bed, such as determining that a detection pad no longer senses the presence of the occupant, then the HVAC system may be triggered to change to daytime settings.
In some embodiments of the invention, the occupancy detection system may be incorporated into a variety of other household devices, other than a bed or bedding system. For example, an occupancy detection system may be incorporated into a door mat, an area rug, and/or a stairway of a home for indication of occupancy presence. For example, in one embodiment, the occupancy detection system may be incorporated into a runner on a basement stairway. Based on a determination of occupancy, the system may trigger an audible alarm to alert that presence is detected, such as alerting a warning signal when a child's presence is detected near basement stairs.
Having described various embodiments of detection using the occupancy detection system, exemplary methods for implementing the occupancy detection system are discussed with reference to
At block 268, the occupancy detection system continues to check whether the first and second sensors have been triggered. If the sensors have not been triggered, at block 270, a timer may be initiated to turn off the light at block 266 after a specified interval of time has passed. In other words, the system will not wait all night for both occupants to get into bed before turning off the lights. Alternatively, if a timer is not initiated, the method returns to block 268 where the system continues to check for a triggering of the first and second sensors before turning off the LED. In one embodiment, a user may indicate bed system that only one occupant is present, which may permit the system to only require detection from a single sensor before turning off the lights.
Turning now to
With reference finally to
At block 292, the occupancy detection system continues to check whether the first or second sensor has been triggered. If neither sensor has been triggered, at block 294, a timer may be initiated to turn off the light at block 290 after a specified interval of time has passed. Alternatively, if a timer is not initiated, the method returns to block 292 where the system continues to check for a triggering of the first and second sensors before turning off the LED.
As will be understood, although the examples of
Accordingly, in a single-occupant embodiment, undermount LED lighting on an adjustable bed may remain on if the user/occupant is not present, and may be turned off once the occupant is detected. In one embodiment of a dual-occupant detection system, the software associated with the sensors may be programmed such that the presence of both users is required before a feature is activated/altered (e.g., both occupants must be present in the bed before the lights will turn off). In another embodiment of a dual-occupant detection system, the system may require that at least one user is present before the lights can be turned off. Further, once the first occupant is present, the system may automatically trigger a timer for turning off the lights without requiring the second occupant to be present in the bed (i.e. a first occupant need not sleep with the lights on all night). However, if the second occupant enters the bed before the timer is complete, the triggering of the second sensor may initiate turning off the lights (without requiring the system to fulfill the entire timer waiting period).
In one embodiment of the invention, a single-occupant system may utilize two sensors for detecting occupancy in an automated bed. The first sensor may make a determination of presence of an occupant in the bed, thereby triggering the turning off of bed lighting (or other associated bed features) without requiring the second sensor to be triggered. As the occupant sleeps, the occupant may shift away from an area of capacitance associated with the first sensor, no longer triggering the first sensor. For example, the occupant may roll from one side of the bed to another. In embodiments, the software of the system may be programmed to allow an amount of delay (i.e. to wait a threshold amount of time) after the first sensor no longer senses an occupant, before triggering an associated feature (e.g. before turning on lights because an occupant has left one side of the bed). If the second sensor detects the occupant within the delay period of time (i.e. before the threshold amount of time expires), then the bed may continue to function as if an occupant's presence has been maintained. In other words, if the first sensor no longer senses the occupant, but the second sensor detects the occupant within a specified amount of time, the lights need not be turned on because the occupant has just moved from one side of the bed to the other.
In one embodiment, a dual-occupant system may be programmed to permit certain features to be triggered that would otherwise inactive with a single-sensory system. For example, in an automated bed system with two sensors, a first occupant may trigger a first sensor and a second occupant may trigger a second sensor. With both sensors triggered, the system may be programmed to turn off the lights associated with the bed (e.g. the underbed LED lighting). If the first occupant exits the bed, underbed lighting may be activated. For example, one occupant may exit the bed to use the restroom in the middle of the night, and lighting may be illuminated even though the second occupant is still present in the bed. In some embodiments, features such as underbed lighting may be occupant-specific, such as underbed lighting only illuminating on the side of the bed associated with the first occupant and/or first sensor.
In some embodiments, underbed lighting features associated with an automated bedding system may include photocell light technology. Accordingly, the underbed lighting may not illuminate until night. As such, in some embodiments, the lights will remain on as long as the room is dark (i.e., it is night) and no occupant is present in the bed (i.e., occupant detection is not sensed according to embodiments of the invention).
In embodiments of the invention, the detection material of the detection pads, wire grid, and/or detection strips and the metalized areas of the mattress topper material are adapted to have a voltage based on proximity of an object to the detection material or metalized area. Such voltage information is collected via the detection material and received by a processor, which determines when a change in voltage satisfies a threshold. Once a particular change in capacitance satisfies a threshold, a corresponding function associated with the automated bed may be initiated. In embodiments, a threshold for initiating a corresponding function includes a particular amount of change in voltage within a particular amount of time. For example, when using capacitance information to turn lights on/off, a particular amount of change in voltage may be required during a particular amount of time before satisfying the threshold indicating that a person has exited the bed (and before the lights may be turned on). Similarly, a particular threshold value of voltage change may be required by the processor, over a particular amount of time, before making a determination that a person has re-entered the bed (and before the lights can be turned off again). In embodiments, a processor continuously receives capacitance monitoring information, and monitors how quickly a change in capacitance occurs (how quickly the delta changes) to determine if a big enough change has occurred in a certain amount of time to satisfy a threshold, and trigger the corresponding function. Accordingly, based on satisfying a particular threshold, various features associated with the automated bedding system 210 may be activated and/or enabled.
With reference now to
At block 304, a filtered noise level is determined, which corresponds to each of the plurality of positions. In one embodiment, the noise level associated with each of the positions of the range of motion profile are received sequentially by running the automated furniture item through a complete cycle and/or range of motion. In one aspect, the noise level associated with each position throughout the range of motion of the automated furniture item is determined and compared to the corresponding startup detection threshold. As such, at block 306, and adjusted detection threshold is generated for the range of motion profile based on the determined filtered noise levels. In some aspects, a first position of the automated furniture item may cause little to no interference with the occupancy detection capabilities of a detection system. As such, the startup detection threshold corresponding to that first position may maintain its original detection threshold as its adjusted detection threshold. In other words, the amount of change in capacitance may remain the same as the detection threshold and baseline level of detection remain consistent with the startup values. By contrast, in another example, a second position of an automated furniture item and/or series of positions of the automated furniture item (while approaching or returning from a particular position) may generate additional noise that results in the determination of an amount of noise to be filtered for that second position, and the determination of an adjusted detection threshold for determining occupancy during articulation to and/or through that position in the range of motion.
In
The perspective view of the position profile characterization 324 in
In
In
In
Turning next to
Accordingly, with reference finally to
Embodiments herein may relate to a standalone capacitance detection device 400 for integration with a furniture item. As shown in
In one embodiment of the invention, manual control device 440 may be configured to receive one or more commands, and communicate the one or more commands, via a manual control device 440 wire assembly, to the standalone capacitance detection device 400. Commands may be communicated, for example, via the manual control device wire assembly 442. In some aspects, the manual control device 440 may be a touch sensing or other control device for receiving manual control indications from a user. As such, the standalone capacitance detection device is configured to carry out both automated functions (by virtue of the capacitance detection sensor 420 and/or control component 430), or by manual input (such as the received commands via the manual control device 440). In some aspects, the manual control device 440 is a single input component, such as a single button, which may receive a plurality of commands based on different input patterns, such as different touch input types and/or gestures. For example, calibration of the standalone capacitance detection device 400 may be initiated by a touch and hold gesture, for a predetermined period of time (e.g., a three-second contact that initiates calibration). Additionally, the manual control device 440 may be configured to receive inputs corresponding to manual changes in lighting settings. For example, the one or more light sources 410 may be dimmed or brightened based upon an input received at the manual control device 440.
Turning now to
In some aspects, the control component 430 may be configured to control one or more light sources 410 using a variety of control and/or activation features, such as a pulse-width modulation (PWM) technique, that intermittently provides power to the one or more light sources 410 at a plurality of on intervals. Further, in some embodiments, the control component 430 may be configured to control one or more features of the capacitance detection sensor 420 such that capacitance may be measured between the plurality of on intervals, or during a light-off phase, at the one or more light sources 410. As such, a change in capacitance may be monitored/detected when the one or more light sources 410 are turned off, thereby eliminating disruptions in the electrical field caused by supplying power to the one or more light sources 410. This can be accomplished, for example, using specialized chipset 434 in the control component 430.
By way of example only, the PWM technique may provide power to the one or more light sources 410 at particular number of intervals per second, such as a light pulsing between 350 and 550 intervals per second. In another aspect, the one or more light sources 410 may be pulsed at a rate between 400 and 500 intervals per second, while in further aspects, the light sources 410 may be pulsed at about 450 intervals per section. As can be appreciated, PWM operates to generate light pulses at intervals such that the one or more light sources 410 appear to be in a constant on-state to a user. That is, the intervals are set such that the off intervals cannot be perceived by a user.
In some embodiments, based on providing power to the one or more light sources 410 at particular intervals per second, one or more features of the control component 430 may be utilized to coordinate both 1) identifying a light-off phase, and 2) sample at least one measurement of the change in capacitance during the identified light-off phase (i.e., between the light-on intervals, such as the exemplary 450 intervals per second). Continuing with this example, the control component 430 may be configured to communicate commands to the capacitance detection sensor 420 at a plurality of times corresponding to times between each of the intervals per second, such as a command to the capacitance detection sensor 420 that indicates a capacitance detection sample is to be taken during the light-off phase of the PWM activation.
In aspects herein, the first capacitance indication corresponds to a capacitance measurement that indicates that occupancy has been detected, and the second capacitance indication corresponds to a measurement that indicates that occupancy has not been detected. Said another way, the first capacitance indication may correspond to a person sitting or lying on a furniture item, and the second capacitance indication may correspond to a person leaving the furniture item. In further aspects, a first instance of capacitance detection may correspond to a change in capacitance from a first capacitance detection to a second capacitance detection (e.g., changing from a user not in the chair, to a seated user's detected presence), while a second instance of capacitance detection may correspond to a change in capacitance from the second capacitance detection to a third capacitance detection (e.g., changing from the seated user's detected presence, to the user exiting the chair).
In some aspects, the control component 430 may be configured to automatically calibrate one or more measurements associated with the standalone capacitance detection device 400. As such, in some embodiments, a control component 430 may be configured to automatically calibrate by measuring a baseline electric field associated with the furniture item and setting an occupancy threshold for associating with the particular furniture item. Calibration may be automatically initiated, for example, upon powering on the standalone capacitance detection device 400. In further embodiments, calibration may be accomplished by measuring a baseline electric field (and/or baseline level of noise) for the furniture item in which the standalone capacitance detection device 400 is integrated. Further, calibration may include setting a presence threshold and/or minimum change in capacitance based on the baseline electric field. In one embodiment of the invention, the presence threshold may correspond to a particular detected change (“delta” or minimum change) in capacitance that represents a change in capacitance associated with a human occupant. As such, a baseline level of detected capacitance may be determined, from which any additional amount of capacitance detected may, once surpassing the presence threshold, generate one or more responses by the standalone capacitance detection device 400.
Additionally, when an occupant or occupants are detected, the presence threshold may be recalibrated. In one embodiment, a presence threshold may be determined at a first timepoint upon a first calibration of the standalone capacitance detection device 400, with no occupant in/on the furniture item. At a second timepoint, a second calibration of the standalone capacitance detection device 400 may be carried out to determine a recalibrated baseline for detection with an occupant in/on the furniture item. As such, the recalibrated standalone capacitance detection device 400 may now monitor for changes in capacitance with reference to the recalibrated baseline and identify additional changes in capacitance, such as the occupant exiting the furniture item, or additional occupants entering the furniture item.
In one embodiment of the invention, when multiple occupants are detected, the presence threshold may be automatically recalibrated to correspond to a minimum change in capacitance for a particular occupant, such as the smallest occupant. Accordingly, automatic calibration may allow the standalone capacitance detection device 400 to be incorporated in any number of different types of furniture items by automatically calibrating the baseline electric field and presence threshold for a given furniture item. In one embodiment, the standalone capacitance detection device 400 may be incorporated into a number of different types of furniture items and remain responsive to changes in occupancy at various timepoints with various numbers of occupants.
Turning now to
Further, universal control component 454 may operate to adjust settings on any number of associated devices 456 associated with the particular person based an identified presence and/or absence. In one aspect, associated devices 456 may be associated with the particular system and/or entity, for example, via LPConnect® and/or LPSense® technology (produced by Leggett & Platt, Inc., of Carthage, Mo.), and stored in, for example, storage 458. Additionally, the universal control component 454 may identify and communicate settings associated with the standalone capacitance detection device 400. For example, if an identified user has a desired setting with respect to light brightness, the setting may be communicated to the standalone capacitance detection device 400, which may implement the desired setting on one or more light sources 410.
As shown in
As shown in
Turning now to the embodiment of
In aspects herein, the first occupancy state may correspond to an occupant initially sitting or lying on a furniture item. Accordingly, the second occupancy state may correspond to an occupant getting up from the furniture item. In some aspects, the detected changes in capacitance and/or occupancy states may be communicated via a network to, for example, a universal control component (described hereinabove with reference to
Accordingly, in one aspect, the method may include changing a lighting state of one or more light sources communicatively coupled with the standalone capacitance detection device from a first state to a second state based on the received second indication of an occupancy state, as shown at block 508. In a first lighting state, the standalone capacitance detection device may be in a “ready” state, continually monitoring for a detectable change in capacitance. Additionally, the second lighting state may correspond to at least one light source of the one or more light sources being on. In some aspects, the one or more light sources may be powered by PWM, such that power is intermittently provided to the one or more light sources at a plurality of on intervals (described in further detail above with reference to
Further, as shown at block 510 when the standalone capacitance detection device is in the second state, the method may include receiving a third indication of an occupancy state, wherein the third indication of occupancy corresponds to a third change in capacitance detected by the standalone capacitance detection device. The third occupancy state may correspond to an occupant returning from having exited a furniture item to a sitting or lying position on the furniture item. In some aspects, the third occupancy state may also correspond to an occupant returning to a lying position from a sitting position. The third change in capacitance may be measured between the plurality of on intervals at the one or more light sources, based on commands received from a control component, based on PWM features.
As can be appreciated, the first occupancy state may indicate that the furniture item is occupied. Further, the second occupancy state may indicate that an occupant is no longer occupying the furniture item. Resultantly, the one or more light sources may be triggered, or turned on, based on detection of the second occupancy state, thereby providing lighting which allows the occupant to navigate the space surrounding the furniture item. While the user is navigating the space surrounding the furniture item and the lighting features are turned on, the system may continuously monitor for a subsequent change in capacitance to indicate that the user has returned. As discussed above, such monitoring may take place between pulses of lighting, as detected during light-off phases of the PWM-cycled lighting feature. Accordingly, the third occupancy state may indicate that an occupant has returned to the furniture item and no longer needs light to navigate. Consequently, the third occupancy state may trigger a command to turn off the one or more light sources. Accordingly, the method may further include communicating a second command for changing a lighting state of the one or more light sources, as illustrated at block 512.
Another embodiment herein relates to an occupancy monitoring system 600 for monitoring use and/or occupancy of furniture items based on capacitance detection, as shown in
In one aspect, the at least one standalone capacitance detection device 602 may comprise a capacitance sensing component 604 for sensing capacitance data, and a control component 606 configured to receive and communicate the capacitance data. The capacitance sensing component 604 may comprise a capacitance detection pad having a size and/or a shape suitable for integration with a plurality of types of furniture items. In some aspects, the control component 606 may be configured to receive and communicate the capacitance data wirelessly (for example, via Wi-Fi, ZigBee, Bluetooth, or any other wireless technology). Additionally, the capacitance data may be communicated via network 610 to other components and/or subcomponents of the occupancy monitoring service 620.
The occupancy monitoring service 620 may include a capacitance data receiving component 622 for receiving the capacitance data; and an occupancy inference engine 624 for determining occupancy data associated with the at least one furniture item based on the capacitance data. The occupancy data associated with the at least one furniture item may comprise, for example, a frequency of use and a duration of use. The occupancy monitoring service 620 may be configured to receive capacitance data from a plurality of standalone capacitance detection devices 602. As a result, the occupancy monitoring service 620 may monitor occupancy for any number of furniture items. For example, a hotel chain may wish to track occupancy of rooms and/or specific furniture items within the rooms across all of their hotels, or for a given hotel. Accordingly, each standalone capacitance detection device 602 may be electronically associated with a given room and or furniture item, such that data specific to the rooms and/or furniture items may be monitored. In some aspects, the standalone capacitance detection devices 602 may each include one or more lighting features that may be turned on or off in response to various detected changes in capacitance throughout the system. For example, if an occupant in a first chair exits a row of chairs, the standalone capacitance detection devices associated with the entire row of chairs may be triggered and the lighting strips associated with each device may illuminate.
In some aspects, the standalone capacitance detection device 602 may be communicatively coupled to one or more furniture accessories 608. As can be appreciated, the one or more furniture accessories 608 may be any number of types of furniture accessories. In a nonlimiting example, a furniture accessory may be a massage motor, a heating element, or an alarm. The massage motor may be configured to activate and deactivate based on detected changes in capacitance. Similarly, the heating element (or cooling element) may be configured to warm a furniture item based on detecting changes in capacitance. Additionally, the alarm may generate an alert, as an audible or communicable indication that an unexpected change in capacitance has been detected, such as when an occupant has fallen out of bed.
In another aspect, a series of coupled standalone capacitance detection devices may illuminate in response to a threshold change in capacitance detection from a single or multiple devices in the series. Additionally, an order of light-off and/or resetting commands may be time-dependent in association with each device in the series, as a result of the initial response to the threshold capacitance change. For example, in a row of coupled chairs, a user may exit one chair, thereby triggering each chair's associated lighting features to illuminate. While the exited user is not detected in their chair, based on a presence indication in the remaining chairs in the series, the lighting features associated with the neighboring chairs in the series may be turned off at a particular timepoint, such as turned off at 5 minutes after the user has exited the chair. As such, the lighting features of the standalone capacitance detection device on the chair with no user may remain illuminated while the lighting features of the occupied chairs in the series are subsequently turned off and returned to a monitoring state. Once the user returns to their chair, the additional change in capacitance may indicate to the currently lit chair that it can return to a ready and light-off status in unison with the series of surrounding chairs.
In some aspects, the system may also include a notification engine 626 configured to generate and communicate one or more notifications. The one or more notifications may be associated with a furniture item and may be generated based on a predetermined threshold change in capacitance being detected. The predetermined threshold change may correspond to a frequency of use and/or a duration of use associated with a furniture item. For example, the at least one furniture item may be a bed having a mattress. Continuing with this example, the one or more notifications may be a notification that the mattress should be flipped. Further, the notification engine 626 may be configured to generate notifications relating to room occupancy. For example, the capacitance data may indicate that a given room is occupied, when the room is supposed to be vacant, and generate a notification indicating that the room is occupied.
From the foregoing, it will be seen that this invention is one well adapted to attain all the ends and objects hereinabove set forth together with other advantages, which are obvious and which are inherent to the structure. It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims. Since many possible embodiments may be made of the invention without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.
Chacon, Ryan Edward, Rohr, William Robert, Madadi, Avinash, Browning, Caleb, Turner, Jason B.
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Feb 28 2018 | TURNER, JASON B | L&P Property Management Company | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 045359 | /0030 |
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